CA1042916A

CA1042916A - Method of making acyl esters of hydroxy alkane sulfonates

Info

Publication number: CA1042916A
Application number: CA209,058A
Authority: CA
Inventors: Herbert G. Landy
Original assignee: Gillette Co LLC
Current assignee: Gillette Co LLC
Priority date: 1973-09-13
Filing date: 1974-09-12
Publication date: 1978-11-21
Also published as: US3880897A

Abstract

ABSTRACT OF THE DISCLOSURE
Hydroxy alkane sulfonates are reacted with fatty acid halides by heating at reflux temperature in anhydrous dialkyl ketone having form 4 to 8 carbon atoms, then cooling below the boiling point and separating the insoluble solid produot from the solution.

Description

This invention relates to a novel method ~or the pre-paration Or acyl esters o~ hydroxy alkane sul~onates such as acyl isethionates and in particular to the u~e o~ a nov01 reaction medium ror the reaction Or ~atty acyl halides and 3alt9 0~ hydro~
alkane ~ulronic acids to ~orm acyl e~tsrs.
Prooe~e~ ~or the e~teri~ication o~ ~¢ids and alcohol~
are well known in the art., many processe~ ~or the synthe~i~ Or acyl ~setihionates being desaribed in detail in ~Sur~Aoe Acti~e : Agents~ Volume I, Schwartz and Perry, New ~ork (1949) at pag0s 94-107, The u9e~ul methods in general compri2e:esterirications carried out with or without a solvent medium and with or without eatalysts under a variety o~ pressure condition3 and in contact with air or with other ~pa¢ial at~ospheres~ !
We have discovered that the reaction Or a saturated or unsQturated ~atty aaid halide having rrom 8 to 22 carbon ato~s with an ammonium or alkali metal ~alt Or a hydroxy alkane sul ~onic acid having rrom 2 to 4 carbon atoms can be aarried out in an anhydrou~ medium in whi¢h there i9 ~ormed a ~lurrg containing the salt and the aoid halide, the medium consisting o~ a d~alkyl ketone having rrom 4 to 8 carbon atoms, by heating the mixture at the boiling point followed by aoolin~ to a temperature below the boiling point and separating the insoluble ~olid product rrom the medium, with ~p0cial advantages o~er proce~se~ previou~ly known.
The rea¢tiDn must be c~rried out under anhydrous con-ditlons in order to avoid hydrolysi~ o~ the ~atty acid h~lide and ~ormation of undersirad by-product, Be¢ause the ketones e~
ployed in the pre~ent invention form azeotropic mi~tura~ wlth water, an7 ~light amount of w~ter present initially as an lm purity can be removed simply by di~tilling O~r the azeotropic mi~ture, The m0dium oan be maintained at it~ boiling point by rerluxing it throughout the reaction thu~ accelerating the rate Or reaction while at the ~ame time ensuring mainten~n¢e o~ anh~dro~s condition~ without the need for an~ 3pecialized equipment. ~e .: -~4~6 rluidity Or the slurry provided by the liquid ketone is al~o advantageous in avoiding the use of ~pecialized equipment for handling and controlling highly viscous mlxtures needed to obtain uni~ormity o~ reaction throughout the mixture and a uni~orm produot~ as i~ the case 1~ the ketone is omitted and the reac-tion carried out in the absenoe of solvent or diluent. By re fluxing the reaction mixture at ambient or atmospheric pressure ef~ective mixing and stirring of the mixture to achie~e unirormity i9 in most casas achieved without the need .~or mechanical stir-~g equipment, the stirring being provided by the boiling o~ themixture~
Moreover, the solubility characteristics Or the ~peci~ied ketonesJ acid halides, hydroxy alkane sulfonates and the reac~
tion products ~ormed are such that the reaction mi~ture remains fluid not only throughout the reaction but even when cooled to room temperature a~ter completion o~ the reaction, unlike the situation when aro~atic media su¢h as benzene and toluene are used~ whioh tend to form gels making di~ficult th0 separation and puri~ioation Or the productO The rlu~dity o~ the reaction mixture of the present invention arter completion Or the reaction greatly ~aoilitates separation and puri~ioation of the product.
The fatty acid halides used in the process o~ the inven tion, o~ which the chlorides and bromides are preferred, parti oularly the ohlorides~ include those saturated and un~aturated ratty acid halides having ~rom 8 to 22 carbon atoms such as caprylyl, pelargonylJ capryl, hendecanoyl9 hendeoenoyl9 lauroyl, myrli.stoyl~ palmitoyl, oleoyl, linoleoyl, stearoyl9 arachidoyl or behenoyl halides. me salts o~ the hydroxy alkane sulronic acids used may be the ammonium or alkali m~tal such a~ sodium~
potas~ium or lithium ~alts o~ ~uch acids having ~rom 1 to 4 carbon atoms, that is, salts having the structure ~I0-R~S03;M9 ._.. where R is a lower alkylene group having from 1 to 4 carbon atoms and M is a cation such as ammonium~ sodium~ potassium or lithium.

~.............................. .

3L~14~9~6 or particular intere~t are the isethionate salts, Consequentl~
the acyl ester produ¢~ ha~ the ~tructure RI~COO-R-$03-M whore R
and M havs the meanings given above and RtC0- is the ~¢yl group ~rom the ~att~ acid halide, ~.e., R~ i9 a saturated or un~turated aliphatic hydrocarbon group havlng ~rom 7 to 21 ¢arbon ~tom~.
The relative molar propartions o~ ~atty acid halide to hydroxy alkane sul~onate may ~ary ~rom 1:2 to 2:1~ prererably rrom 1:1 to l lol~ The reaction oan be carried out without a oatalyst ~imply by heating tho ingredients in the solvent, but pre~rably an alkaline catal~st i9 used suoh a~ an ammonium or alkali ~stal carbonate or bioarbonate in an amount from 5 bo 75 mole per cent o~ the ~atty aoid ~lide.
Any dialkyl ketone having ~rom 4 to 8 oarbon atoms or mixture o~ ~uch keto~s can be e~ployed as the solvent in ths reaction mixture, the reaction being carried out by heating the mixture at a temperature o~ about 70-155C~ Among the diaI~yl ketones which can be used are 2-butanone) 3,3-dimethyl-2-butanona~

2-pentanone, 3-methyl-2-pentanone, 3-pentanone, ~-methyl-3-pentanone, 2,4-dimethyl-2-pentanone~ 2-hexanone, 3-hexanone,

3-methyl-2-hexanone, 5-meth~1-2-hexanone, 4-methyl-3-hexanone, 2-heptanone, ~-heptanone, and 2-methyl-4-heptanone. While j acetom itselr cannot be used, a small amount up to 2 to 3 por--cent by weight o~ acetone may be present as an imp~rity in the ketone or mixture o~ kstone~ which i9 e~ployed~ The amount Or dialkyl ketone solvent can be ~rom 100 to 309 per cent by weight Or the total ratty acid halide and hydroxy alkane sul~onate.
In ~ng ou~ the reaction Or the present proce~s, it . ~
is pre~erred to slurry or ~uspend the hydroxy alkane sulronate, and the ~lkaline catalyqt ir used, in the de~ired ketone or mixture Or ketones, then heat the mixture to the boiling point to distill o~ any traces o~ water present in the rorm o~ an a~eotropic mixture with the ketone, A~ter remo~ing the water and while the mixture is re~lux~ngg the ~atty a~id halide, pre~0rably previou~y -3~

Z9~
heated to about the same temperature, is gradually added to the mixture. Refluxing can be aontinued for ten minutes to 6 hours in ~rder to bring the reaction to completion, depending ~pon the particular reagents and the total volume employed. The reaction mixture is then allowed to cool, permitting precipitation and settling out of the insoluble fatty acid ester product. The product can then be separated from the reaction mixture by fil-tration, centrifugation, or any other conventional procedure, washed and dried in the usual manner.
The extent to which the rea~tion has proceeded, con-sequently the time when heating and refluxing of the reaction mixture can be stopped, can readily be deter~ined by conventional tests. For example, the fatty acid halides are ound to have characteristic infrared absorption bands when in solution in dialkyl ketones, the intensity of absorption being proportional to the concentration of the acid chloride. As a consequence, i monitoring of the infrared absorption can be used as an indication of extent of raaction.
The products of the process of the present invention are useful as detergents, wetting a~ents, or foaming agents in a variety of compositions such as textile treating compositions, cosmetic compositions, industrial cleaning products, etc. and as matrix builders in aqueous adhesive compositions.
The following specific examples are intended to illustrate more fully the nature of the present invention without acting as a limitation upon its scope.

_ _ There was introduced into a flask 320 grams (about 2.16 moles) of finely-ground sodium isethionate and 21 grams (0.2 mole) of anhydrous sodium carbonate. There was then in-troduced about 2.4 liters (1900 grams) of 4-methyl-2-pentanone (methyl i~obutgl ketone). ~he mixture was hoated to the boiling point and there wa~ di~tilled o~ approximatel~ one-hal~ liter (400 grams) o~ the ke~one solvent~ thu~ remo~ing as an &zeotropi¢
mixture with the ketone whatever small amount o~ water was present as an impurity~ About 600 ~rams o~ 3tsaroyl chloride ~1.98 moles) was heated to 30C~ and placed in a dropping runnel ~rom which lt was introduced gradually over a thirty-m~ute period into the re~luxin~ ~etone solutlon Or sodlum i~ethiona~e and ~odium car-bonate which Wa9 ~aintained at re~ temperQture. Heat~ng and I0 r0rluxing was ¢ontinued ~or an additional 6 hours until sub-stantiall~ all o~ the ~earoyl ahloride had reaated as ~ndicated by in~rared absorption mea~urement~ me reaction mixture W~9 thsn oooled to 75~85C~, ril~ered~ and the insoluble solid product wa~ slurried in about 2 liters of boiling methyl isobutyl ketone and again ~iltered. The moist ~iltar ¢ake was then ~lurried in about 7 liter~ o~ deionized water and the pH wa~ ad~usted to 900 by adding 10% aqueoua ~odium hgdroxideO The product was ~eparated ~rom tha water by ~iltration and the water ~lurrying procedure was repeatedv tho product rinally being dried undsr vaauum at 65C. for about 24 hour~0 The product weighed ap-proximately 700 gra~s (about 85% o~ the theoretical ~ield ba~ed on ~tearoyl ahloride) and displayed a pH o~ ~.3 in the ~orm o~
a 1% by weight solution in water, It ¢ontained about 1~7% ~ree ~atty aaidO
The procedure desaribed above wa~ rep3ated exaept that there wa9 used in place o~ the meth~l isobutyl ketone as the solvent~ eaah Or the rollowing ketons~ in Ssquenoe~ the par cent yield in eaoh ~ase being the per aenta~e of theoretioal yield based upon stearoyl chloride:
Ketone % Yield Methyl ethyl ketonel 45.2 2-Pentanone 70~3 2-Hexanone2 71~5 ~4Z916 EXAMPIE ~-10 Into a one-liter three~ne¢k round bottom ~lask ritted with a me¢hanical stirrer and condenser provided with a drying tube9 thare were introdu¢ed 320 milliliter~ (256 gram~) o~ 4-methyl-2-pentanPne9 and amount~ 01 sodlum isethionate and o~ sodium ¢arbonate as ~et ~orth in khe ~ollowing tableO All gla~sware had previously been dried at 120C. and ~ssem~led while hot. The ~lask was heated by means o~ an oil bath and when the temperatura of the bath reaohed 120~C,~, there wa~ introduced in 4 increment~
10 at 10 minute interval~ an amount o~ ea~h Or the ~a.~ty a¢id ~hlorides li~ted in the ~ollowing table corresponding to 0.33 moleO During the introduction o~ the ~atty acid chloride9 tho bath temperature wa3 inorea~ed to 130-140C. to ensure that re~
fluxing continuedO Heat~ng and refluxing was continued ~or 10 minutes after the introduction of the last ~ncrement, and the reaction mixture wa~ ~hen cooled and ~iltered to remove the solid insolu~le reaetion produ¢tO The produ¢t wa~ washed and puri:Eied as de~cribed in E~ample 19 the water wa~hinl3~ being repeated until all chloride had been removed as shown by a silver 20 nitrate solution testO The yield o~ product obtained expressed ~erlux l;ime approximatelg 12 hours.
Reaction mixtur~ ~oamy; high speed agitation used to oontrol the roamingO
a~ a per oentage o~ the theoretioal yield ba~ed upon tha ~atty aoid Gh~oride employed was as ~et ~orth in the tableO
Moles Mole~ o~ Mole3 of O~ A~id Sodium ~odium Yield Acid Chlorid~ Chlorido Isethionate ~ %
5 Stearoyl 00330 o,3bo 0,165 69 6 Palmito~l 0,363 0.396 00036 66 7 Myristoyl 00405 Oo442 o,o40 69 8 Lauroyl o.460 00500 O. o46 77 9 Capryl 00250 00272 00025 83 10 Capr~lyl 0.,610 0.670 0.061 ~3 EXAMPLES 1~-1? ~ 4 ~9 1~
me proaedure of Exa~ple 1 wa~ repeated u~ing in place o~ stearoyl chloride approximately 2 moles o~ a mixture ¢ontain-ing 40~ by weight of arachidic a¢id chloride and 60~ by weight o~
behenic acid chlorideO The product amaunted to approximately 75% by weight o~ the theoretical based on the amount Or fatty acid chlorideO

Claims

The embodiments of the invention in which an exclusive property or privilege is claimed are defined as follows:

1. The method of making an acyl ester of a hydroxy alkane sulfonate which comprises heating at the boiling point a mixture of a member of the group consisting of ammonium and alkali metal salts of a hydroxy alkane sulfonic acid having from 2 to 4 carbon atoms with an acylating agent selected from the group consisting of saturated and unsaturated fatty acid chlorides and bromides having from 8 to 22 carbon atoms in an anhydrous medium for said salt and for said acylating agent consisting of a dialkyl ketone having from 4 to 8 carbon atoms, cooling to a temperature below the boiling point, and separating the insoluble solid product from the solution.

2. The method as claimed in claim 1 in which the molar proportion of salt to acylating agent is from 1:2 to 2:1 and the acylating agent is acid chloride.

3. The method as claimed in claim 2 in which the amount of said medium is from 100% to 300% by weight of the total salt and acid chloride.

4. The method as claimed in claim 3 in which there is added to the reaction mixture a member of the group consisting of ammonium and alkali metal carbonates and bicarbonates in an amount from 5 to 75 mole percent of the acid chloride.

5. The method as claimed in claim 1 in which there is included in the mixture a member of the group consisting of ammonium and alkali metal carbonates and bicarbonates in an amount from 5 to 75 mole percent of the acylating agent.

6. The method as claimed in claim 1 in which an iseth-ionate is first slurried in the ketone, the mixture is boiled to dehydrate it by evaporating a portion of the ketone from the mixture, and the acylating agent is introduced into the mixture gradually while heating and refluxing the mixture.

7. In a method of making an acyl isethionate which comprises reacting a member of the group consisting of ammonium and alkali metal isethionates having two carbon atoms with a saturated or unsaturated fatty acid chloride having from 8 to 22 carbon atoms in a molar ratio to said isethionate from 1:2 to 2:1 and with a member of the group consisting of ammonium and alkali metal carbonates and bi-carbonates, the amount of said carbonates and bicarbonates being from 5 to 75 mole per cent of the acid chloride, the steps which comprise using as the medium a dialkyl ketone having from 4 to 8 carbon atoms in an amount from 100% to 300% by weight of the total isethionate and acid chloride, mixing said isethionate and said carbonate or bicarbonate first with said dialkyl ketone, heating the mixture to the boiling point to evaporate sufficient dialkyl ketone to de-hydrate the mixture, adding the acid chloride gradually to the mixture while heating and refluxing the mixture, and cooling the mixture to a temperature below the boiling point and separating the insoluble acyl isethionate product from the mixture.